Plant Essential Oils as Repellents and Deterrents to Agricultural Pests

Chapter 5

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Murray B. Isman* and Saber Miresmailli Faculty of Land and Food Systems, University of British Columbia, Vancouver, British Columbia V6T1Z4, Canada *E-mail: [email protected]

The concept of using non-lethal behavior-modifying substances for management of arthropod pests of agricultural crops has been long touted but as yet largely unexploited on a commercial scale. Numerous natural products have demonstrated repellent, antifeedant or oviposition deterrent activities in laboratory bioassays using pest insects, but consistent efficacy under field conditions has seldom been achieved. This results in part from unpredictable interspecific differences in responses to particular compounds, and in part from the ability of insects to habituate to deterrent compounds on repeated or continuous exposure. Plant essential oils represent a relatively new class of natural insecticides efficacious against a wide range of pests. While their neurotoxicity to insects and mites is widely recognized, there is strong anecdotal evidence that in some contexts efficacy could be attributed in part to their actions as behavior modifiers (i.e. as repellents or deterrents). Results of behavioral bioassays that explore the potential of certain essential oils and their constituents as repellents and deterrents to some other agricultural pests will be presented. In addition, changing composition of terpenoid emissions from essential oils over time will be discussed in relation to their biological effects. For over 60 years insect pest management has relied extensively, and often exclusively, on the use of acutely toxic synthetic chemical insecticides. The dominant products used have evolved over this period, from the chlorinated hydrocarbons (e.g., DDT and the cyclodienes) to the © 2011 American Chemical Society In Recent Developments in Invertebrate Repellents; Paluch, G., et al.; ACS Symposium Series; American Chemical Society: Washington, DC, 2011.

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organophosphates and carbamates (e.g., parathion and carbaryl), to the pyrethroids (e.g., permethrin) and most recently to the neonicotinoids (e.g., imidacloprid) (Thacker, J.R.M. An Introduction to Arthropod Pest Control; Cambridge University Press: Cambridge, U.K., 2002). These insecticides have been highly favored by growers owing to the wide assortment of products and formulations, their demonstrated efficacy and cost/benefit ratios in large scale agricultural practice, and their rapid, “curative” action when pest populations approach economic thresholds and threaten economic crop loss. But history tells us that reliance and overuse of these products has come with hidden or at least less obvious costs – toxicity to a wide array of non-target organisms, widespread soil and groundwater contamination, poisonings of pesticide applicators and farmworkers and concern for chronic health impacts in the general population as a consequence of pesticide residues in food (Benbrook, C.M. Pest Management at the Crossroads; Consumers Union: Yonkers, NY, 1996).

Concerns over environmental and human health impacts have led to increasingly restrictive regulation of chemical insecticides, particularly in North America, the European Union and Japan, and indeed many insecticide products that once dominated agricultural pest management have disappeared from the market (3). Recent pesticide use data from the State of California, a jurisdiction with among the most intensive pesticide use in the world, provides strong evidence of the trend toward reduced pesticide use, as shown in Table 1. While the quantities of many important insecticides applied have declined, the overall quantities still used remain very large. Indeed, conventional insecticides, once touted to be displaced by biopesticides by 2000, continue to be the cornerstone of agricultural insect pest management. The US EPA introduced the concept of “reduced risk” insecticides in 1992. Insecticides meeting the criteria of reduced risk (viz. less toxicity to nontarget organisms, reduced probability of groundwater contamination, reduced probability of resistance development) include microbials, botanicals, synthetic insect growth regulators, and the most recently developed conventional products that act through novel mechanisms-of-action. Given the popular and intuitive appeal of biopesticides (includes microorganisms, naturally occurring compounds and pheromones), it is interesting to note the 50% reduction in their use in California from 1998-2008, mirroring reductions for some of the traditional insecticides the biopesticides were expected to replace (Table 1). Moreover, the reduction in use of biopesticides over the decade is more than double that of all pesticides combined (-25.5%).

68 In Recent Developments in Invertebrate Repellents; Paluch, G., et al.; ACS Symposium Series; American Chemical Society: Washington, DC, 2011.

Table 1. Use of selected insecticides in California in 1998 and 2008 Insecticide

Pounds applied 1998

Pounds applied 2008

% change

2,451,980

1,350,399

-45.0

Diazinon

901,388

256, 218

-71.6

Malathion

663,200

474,863

-28.4

Methomyl

666,694

243,064

-63.5

Phosmet

645,380

339,696

-47.4

Biopesticides (all)

1,440,924

695,553

-51.3

Mineral and petroleum oils

27,254,084

25,716,688

-5.6

All pesticides

216,811,299

161,531,155

-25.5

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Chlorpyrifos

SOURCE: California Department of Pesticide Regulation (4)

Plant Essential Oils as Insecticides In spite of decades of research worldwide, only a handful of plant natural products have been successfully commercialized as botanical insecticides. Among those currently in the marketplace are pesticides based on plant essential oils. Facilitating commercialization of essential oil-based pesticides in the U.S. has been the exemption of certain oils from EPA registration, owing to their widespread use in foods, beverages and cosmetics. Well known examples are oils of rosemary, cinnamon, cloves, lemongrass, thyme and various mint species (5). That most of those are available as industrial commodities dramatically lessens the issues of supply and cost. Further advantages of these oils as insecticides are their relatively low acute mammalian toxicity (and therefore margin for human safety), their relatively short half-lives in the environment, and conversely, their rapid knockdown effect on many insects and related arthropods. Chemically, plant essential oils are characterized by often complex mixtures of monoterpenes, sesquiterpenes and related phenols. It is these low molecular weight volatile compounds that account for the fragrances of the oils. In isolation, a number of these terpenoids have demonstrated contact and fumigant toxicity to insects; there is evidence that they also have sublethal repellent and/or deterrent effects in some insects (5). Many of these biological actions may be attributable to their action as agonists of octopamine (6–8), an arthropod neuromodulator, although there is emerging evidence that some oils or their constituents may have alternative targets in the insect nervous system (9). An interesting aspect of the toxicity of plant essential oils to insects and mites is the potential internal synergy of constituents – those deemed inactive in isolation have been demonstrated to boost the potency of those that are active in isolation (10, 13). Owing to the useful bioactivity and relative availability of essential oils, together with their regulatory exemption in the US, insecticides based on certain oils have been commercialized for industrial, agricultural and consumer 69 In Recent Developments in Invertebrate Repellents; Paluch, G., et al.; ACS Symposium Series; American Chemical Society: Washington, DC, 2011.

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markets. While particularly effective for pest control in the home and garden, an agricultural insecticide based on rosemary and peppermint oils as active ingredients has proven successful against softbodied insects and mites in several crops. For example, a field trial for control of western flower thrips, Franklinella occidentalis, on strawberry in Salinas, California demonstrated that the essential oil-based product was more efficacious against thrips three weeks after treatment than spinosad, a fermentation-based insecticide prized by organic growers (14). Moreover, a tank mixture of the essential oil product and spinosad, each at one-half of their respective recommended label rates, was as effective as spinosad at the recommended rate. But the field efficacy observed raises an interesting question: does behavioral disruption – deterrence or repellence – contribute to overall efficacy?

Plant Essential Oils as Repellents and Deterrents We had previously demonstrated in the laboratory that 1% rosemary oil can repel twospotted spider mites for at least 48 hours in a bean leaf choice test (15), and similarly that the oil reduced oviposition of greenhouse whitefly on tomato plants sprayed with 1% rosemary oil (16). Greenhouse experiments in Japan also demonstrated that rosemary oil could disrupt the settling behavior of green peach aphids on host plants ((17), also see (5)). Do these effects occur under field conditions? How persistent might the repellent effect be in the field if the oils evaporate rapidly from plant surfaces? We chose to explore the repellent/deterrent effect of plant essential oils under controlled laboratory conditions to better understand the dynamics of insect response over time to the oils. It is worth noting here that a repellent, by definition, causes oriented movement of an organism away from the source, whereas a deterrent simply prevents a behavior. In practice these actions can be difficult to distinguish which may explain why the terms of often used interchangeably. Note, for example, that we speak of “insect repellents”, whereas many so-called products might actually work by disrupting alighting or probing behaviors of mosquitoes and other bloodfeeders, rather than causing them specifically to fly away from our skin. In addition to insect behaviors, we were also interested in the pattern of volatilization of an essential oil – do the major constituents all evaporate at the same rate, or does the composition of volatiles “evolve” over time? To address these questions we conducted laboratory bioassays with two crop pests and one stored product pest. We tested the responses of adult twospotted spider mites, Tetranychus urticae (Acari: Tetranychidae) and confused flour beetles, Tribolium confusum (Coleoptera: Tenebrionidae) to rosemary oil, and those of 1st instar obliquebanded leafrollers, Choristoneura rosaceana (Lepidoptera: Tortricidae) to a commercial insect repellent (EcoSMART Insect Repellent™). All three species were maintained in continuous culture for at least three months in the absence of pesticides. Mites were reared on greenhouse-grown broad bean plants, beetles were reared on bran flakes, and leafrollers were reared on an artificial medium. 70 In Recent Developments in Invertebrate Repellents; Paluch, G., et al.; ACS Symposium Series; American Chemical Society: Washington, DC, 2011.

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To analyze volatiles emanating from the oil and repellent we used a zNose™ – an ultrafast portable gas chromatograph. The zNose™ inlet, valve and initial column temperature were 200°C, 165°C, and 40°C, respectively. During analyses, the column temperature was increased at 10°C/sec to 200°C. The surface acoustic wave (SAW) sensor was kept at 50°C and the trap at 250°C. The helium flow during the 10 sec sampling period was set at 3.00 ccm. The sampling period was set for 10 sec at a sample flow of 20 ccm, after which the system switched to 20 sec of data acquisition. Thereafter, the sensor was heated to 150°C for 30 sec, and parameters (see above) were reset. The zNose system was tuned with an nalkane solution and calibrated with neat reagents prior to its application in each experiment. As with other types of sensors, the response of the SAW sensor is proportional to the mass of the eluate, and calibration with the alkane standards permits quantitative analyses (see ref. (11) for a full discussion). In the first experiment, we studied the effect of rosemary oil volatilization on the behavior of twospotted spider mites. The test arenas consisted of 12 glass plates (8 x 15 cm), ten treated with rosemary oil and two untreated as controls. Each plate was divided into 7 equally spaced regions and marked accordingly. For the treatment plates, the first region was painted with 20 µl of rosemary oil using a pipette. Every ten minutes, five adult mites were placed on the second (adjacent) region of the plate. Positions of these mites were then recorded for 10 minutes after their placement. The pattern of rosemary oil volatiles on each plate was recorded by placing the zNose over the first region of the plate immediately after placement of the mites. After 10 minutes mites were removed from the plate and replaced by naïve mites with no prior exposure to rosemary oil. The experiment ran for one hour, and was repeated twice. Based on previous analysis of ten independent commercial samples of rosemary oil, the major constituents of rosemary oil are 1,8-cineole (52.1%), α-pinene (9.8%), camphor (9.0%), β-pinene (8.2%), camphene (4.9%) and d-limonene (3.8%)(figures in parentheses are averages) (12). Our results indicated that overall, there was a significant effect of time on volatilization pattern of rosemary oil constituents (F [5, 44] = 101.984, p < 0.05; Wilk’s lambda= 0.000)(Figure 1). Due to considerable variability, we did not find an overall statistically significant effect of compounds on the positions of mites on the test plates over the course of experiment. However, pair-wise comparisons of means showed that certain compounds had a significant effect on the position of mites at certain time intervals. As seen in Figure 1, the mites on the test plates moved away from the rosemary oil source at times matching peak release of 1,8cineole, d-limonene and camphor. In the second experiment, we studied the effect of rosemary oil on the behavior of adult flour beetles. The test arenas consisted of six 8x15 cm glass plates (5 treatments and 1 control). We covered the center of each treatment plate with a Petri dish (6 cm diameter) and applied 1 ml of rosemary oil evenly across the glass plate outside of the Petri dish and then removed the Petri dish and marked the untreated area. The zNose was then placed over the treated part of the plate. Five adult beetles were placed on the center of the plate. We measured the volatilization of rosemary oil constituents upon introduction of the beetles to the arena and every five minutes thereafter. Numbers of beetles that crossed into the treated zone were 71 In Recent Developments in Invertebrate Repellents; Paluch, G., et al.; ACS Symposium Series; American Chemical Society: Washington, DC, 2011.

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recorded every 5 minutes at which time beetles were replaced with five naïve beetles. The experiment ran for140 minutes after application or rosemary oil on the plates, and was repeated three times. As in the first experiment, there was a significant effect of time on volatilization pattern of all compounds (F [27, 251] = 7603, p < 0.05; Wilk’s lambda= 0.000) (Figure 2). Volatilization pattern of compounds also had a significant overall effect on the percentage of beetles crossing into the treated zone (F [6, 246] = 1.296, p < 0.05; Wilk’s lambda= 0.969). Rosemary oil prevented beetles from crossing into the treated zone for 100 minutes, but 120 minutes after treatment, all naïve beetles “crossed the line” (Figure 2).

Figure 1. Comparing volatilization pattern of rosemary oil major constituents with position of naïve spider mites in a test arena over 60 minutes. Data points represent mean ± SD (n=20).

72 In Recent Developments in Invertebrate Repellents; Paluch, G., et al.; ACS Symposium Series; American Chemical Society: Washington, DC, 2011.

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Figure 2. Comparing volatilization pattern of rosemary oil major constituents with percentage of naïve beetles crossing into the treated zone over time. Points and bars represent mean ± SD (n=15). In the third experiment, we studied the effect of a commercial insect repellent on 1st instar obliquebanded leaf roller larvae. Six test plates were set up as in the second experiment. Treatment plates were treated with 1 ml of the commercial insect repellent. We installed a light source (40W clear light bulb) on one side of each plate to induce movement in the positively phototactic larva. Major constituents in this product include geraniol (0.6%), eugenol (0.4%), 1,8-cineole (0.2%) and citral (0.2%)(R. Bradbury, unpublished data). Two larvae were placed in the center of the plate (untreated zone) at each data collection interval and allowed to move for five minutes. Numbers of larvae that crossed into the treated zone were recorded. Volatiles were analyzed and naive larvae added every five minutes for a total of 140 minutes. Again there was a significant effect of time on the volatilization pattern of the repellent compounds (F [26, 107] = 263.914, p < 0.05; Wilk’s lambda= 0.000). The volatilization pattern of compounds did not have a statistically significant overall effect on the percentage of larvae crossing the treatment line. Larvae started to cross the treatment line after 110 minutes; all larvae crossed into the treated zone after 130 minutes (Figure 3). 73 In Recent Developments in Invertebrate Repellents; Paluch, G., et al.; ACS Symposium Series; American Chemical Society: Washington, DC, 2011.

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Figure 3. Comparing volatilization pattern of insect repellent major constituents with percentage of naïve larvae crossing the treatment line over time. Points and bars represent mean ± SD (n=5). Previously, we showed that presence or absence of certain constituents in a mixture could significantly effect the efficacy of essential oil-based botanicals as contact pesticides (10, 12). Results of the present study provide new insight in the behavioral impacts of these products as insect and mite repellents. Should these essential oils be used as repellents, efficacy could be tied to the volatilization pattern of constituents. Our study shows that the volatilization pattern of essential oils changes over time. In the case of rosemary oil (Figures 1 and 2), some constituents will only be present in the headspace after the level of other constituents decreases (i.e., d-limonene and camphene versus 1,8-cineol and camphor). These interactions can affect the behavior of insects and mites. Our first experiment confirms this: mites were repelled the most between 20 and 40 minutes when most of the major constituents were present at maximum levels. In the second and third experiment, we demonstrated that there is a threshold for repellence, which is closely related to the volatilization level of constituents. The compounds might be still present as a residue of the mixture on the surface where it was applied, suggesting a deterrent effect rather than a repellent one. However, we did repeatedly observe leafrollers and beetles approach the treated zone and turn away without touching it, suggesting a true repellent effect albeit at close range. This repellence decreased when the volatilization levels decreased. 74 In Recent Developments in Invertebrate Repellents; Paluch, G., et al.; ACS Symposium Series; American Chemical Society: Washington, DC, 2011.

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With the commercial insect repellent, we observed a gradual change in the level of volatiles, while for rosemary oil, volatiles decreased suddenly after 100 minutes. Although the reason for this phenomenon is not immediately clear, it might be possible to develop a particular mixture and/or formulate it such that it maintains levels of volatiles that decay gradually over longer periods of time, therefore, remaining more biologically effective. Microencapsulation or nanoparticle technology may be useful techniques for achieving prolonged release of volatiles, as has been demonstrated with garlic oil (18).

Insect Antifeedants (and Oviposition Deterrents) as Crop Protectants Voluminous scientific literature indicates that terrestrial plants are a rich source of natural products that deter feeding of one or more species of insect under laboratory conditions. These observations should not be surprising: the modus operandi of plant chemical defense is primarily based on discouraging herbivory, rather than killing insects outright. This may explain why so few botanical insecticides have been commercialized – most plant natural products are not acutely toxic to insects, at least at doses comparable to those for synthetic insecticides (19). The concept of using insect antifeedants as nontoxic crop protectants is intuitively appealing and has been the subject of considerable research (20). While there have been a handful of studies reporting moderate efficacy of antifeedants under field conditions, not a single antifeedant has been commercialized for crop protection to date. Why is there such a big disconnect between laboratory science and commercial application in this regard? The answer may lie in the plasticity of insect sensory physiology and feeding behavior. In the vast majority of studies reporting antifeedant effects of plant compounds, naïve insects are utilized and then discarded; seldom are the same insects tested twice. In so doing, many investigators have failed to observe an important phenomenon of insect behavior, and one that bears on the potential efficacy of antifeedants as crop protectants – habituation. Almost 15 years ago we demonstrated that the Asian armyworm Spodotera litura habituated to the extremely potent antifeedant azadirachtin, when challenged with azadirachtin-treated leaf discs on successive days (21). By the third day, feeding deterrence had dropped to 10%, compared to 60% for naïve larvae on the first day of testing. Moreover, when we exposed larvae to azadirachtin continuously, they habituated almost completely after 4.5 hours of feeding (22). That this phenomenon was not restricted to azadirachtin was later shown in our studies with the cabbage looper Trichoplusia ni, which habituated fully to several known antifeedants, both terpenoid and phenolic, and to complex plant extracts. Moreover, we even found that exposing loopers to certain feeding deterrents in the last larval stage negated the oviposition-deterring properties of those compounds to the subsequent moths (23). In other words, the memory of the compounds to which the larvae habituated was retained through metamorphasis from larva to pupa and from pupa to adult. In some cases, what is normally an oviposition deterrent to naïve moths became an oviposition stimulant for the “experienced” 75 In Recent Developments in Invertebrate Repellents; Paluch, G., et al.; ACS Symposium Series; American Chemical Society: Washington, DC, 2011.

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moths. This is all the more remarkable when considering that larvae and adult do not share gustatory organs; larval gustatory sensilla are found exclusively on the mouthparts, whereas adult lepidopterans “taste” plants using chemosensilla on their tarsi (feet) and on the ovipositor (egg-laying organ) itself. What this means in practical terms is that an insect in constant contact with a deterrent applied to a crop may quickly overcome the deterrence and feed with impunity, unless of course the antifeedant also has some deleterious physiological effect on the insect, as in the case of azadirachtin. While azadirachtin is a potent antifeedant to many (but not all) insects, it is likely its insect growth regulatory activity that accounts for the efficacy of neem-based insecticides in commercial use (3). Habituation to sex attractant pheromones has been observed, and in some situations could be a factor limiting the success of mating disruption programs based on mass release of synthetic pheromone (24). Little is currently known about the potential for habituation in insects to repellent volatiles, but it would be logical to assume that this could pose a limitation to the use of repellents as crop protectants. One aspect of synthetic insecticides that has greatly facilitated their acceptance by growers is their consistent efficacy in most insect management situations and contexts. The user need not have a detailed understanding of insect physiology or toxicology, and there is often a wide window with respect to timing of applications. In contrast, the use of insect behavior-modifying chemicals for crop protection requires a sound understanding of insect behavior and ecology. Efficacy for products of this type may depend to a far greater extent on such factors as timing, temperature and the formulation of the active ingredients compared to that of conventional insecticides. Our understanding of how and when repellents or deterrents could be effective for crop protection is very thin at the moment. In the case of the essential oil-based insecticides, it is entirely possible that much of the efficacy already seen in the field against certain pests may be a consequence of repellence rather than toxicity. Thus continued research is warranted, including observational studies in the field and further development in the laboratory of potential alternative crop protection products. The decline in the use of conventional insecticides (Table 1) provides an obvious impetus for such research.

Acknowledgments Based on a symposium paper presented at the 238th ACS Annual Meeting in Washington, DC, August 16, 2009. We thank Nancy Brard for technical assistance, Pacific AgResearch for permission to use their unpublished data and Cristina Machial for comments on the manuscript. Supported by grants from MITACS, NSERC, Ecosafe Natural Products Inc. and EcoSMART Technologies Inc.

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